Biallelic MADD variants cause a phenotypic spectrum ranging from developmental delay to a multisystem disorder.

In pleiotropic diseases, multiple organ systems are affected causing a variety of clinical manifestations. Here, we report a pleiotropic disorder with a unique constellation of neurological, endocrine, exocrine, and haematological findings that is caused by biallelic MADD variants. MADD, the mitogen-activated protein kinase (MAPK) activating death domain protein, regulates various cellular functions, such as vesicle trafficking, activity of the Rab3 and Rab27 small GTPases, tumour necrosis factor-α (TNF-α)-induced signalling and prevention of cell death. Through national collaboration and GeneMatcher, we collected 23 patients with 21 different pathogenic MADD variants identified by next-generation sequencing. We clinically evaluated the series of patients and categorized the phenotypes in two groups. Group 1 consists of 14 patients with severe developmental delay, endo- and exocrine dysfunction, impairment of the sensory and autonomic nervous system, and haematological anomalies. The clinical course during the first years of life can be potentially fatal. The nine patients in Group 2 have a predominant neurological phenotype comprising mild-to-severe developmental delay, hypotonia, speech impairment, and seizures. Analysis of mRNA revealed multiple aberrant MADD transcripts in two patient-derived fibroblast cell lines. Relative quantification of MADD mRNA and protein in fibroblasts of five affected individuals showed a drastic reduction or loss of MADD. We conducted functional tests to determine the impact of the variants on different pathways. Treatment of patient-derived fibroblasts with TNF-α resulted in reduced phosphorylation of the extracellular signal-regulated kinases 1 and 2, enhanced activation of the pro-apoptotic enzymes caspase-3 and -7 and increased apoptosis compared to control cells. We analysed internalization of epidermal growth factor in patient cells and identified a defect in endocytosis of epidermal growth factor. We conclude that MADD deficiency underlies multiple cellular defects that can be attributed to alterations of TNF-α-dependent signalling pathways and defects in vesicular trafficking. Our data highlight the multifaceted role of MADD as a signalling molecule in different organs and reveal its physiological role in regulating the function of the sensory and autonomic nervous system and endo- and exocrine glands.

Identification of Brain-Specific Treatment Effects in NPC1 Disease by Focusing on Cellular and Molecular Changes of Sphingosine-1-Phosphate Metabolism.

Niemann-Pick type C1 (NPC1) is a lysosomal storage disorder, inherited as an autosomal-recessive trait. Mutations in the Npc1 gene result in malfunction of the NPC1 protein, leading to an accumulation of unesterified cholesterol and glycosphingolipids. Beside visceral symptoms like hepatosplenomegaly, severe neurological symptoms such as ataxia occur. Here, we analyzed the sphingosine-1-phosphate (S1P)/S1P receptor (S1PR) axis in different brain regions of Npc1-/- mice and evaluated specific effects of treatment with 2-hydroxypropyl-ß-cyclodextrin (HPßCD) together with the iminosugar miglustat. Using high-performance thin-layer chromatography (HPTLC), mass spectrometry, quantitative real-time PCR (qRT-PCR) and western blot analyses, we studied lipid metabolism in an NPC1 mouse model and human skin fibroblasts. Lipid analyses showed disrupted S1P metabolism in Npc1-/- mice in all brain regions, together with distinct changes in S1pr3/S1PR3 and S1pr5/S1PR5 expression. Brains of Npc1-/- mice showed only weak treatment effects. However, side effects of the treatment were observed in Npc1+/+ mice. The S1P/S1PR axis seems to be involved in NPC1 pathology, showing only weak treatment effects in mouse brain. S1pr expression appears to be affected in human fibroblasts, induced pluripotent stem cells (iPSCs)-derived neural progenitor and neuronal differentiated cells. Nevertheless, treatment-induced side effects make examination of further treatment strategies indispensable.

Novel mutations in the GJC2 gene associated with Pelizaeus-Merzbacher-like disease.

Inherited white matter disorders of the central nervous system frequently are degenerative and progressive clinical entities. They are classified into myelin disorders, including hypomyelination, dysmyelination, demyelination, and myelin vacuolization, but also astrocytopathies, leuko-axonopathies, microgliopathies, and leuko-vasculopathies. Hypomyelinating leukodystrophy is the main feature of Pelizaeus-Merzbacher disease (PMD) and Pelizaeus-Merzbacher-like disease (PMLD1). PMD- and PMLD1-affected patients display comparable neurological symptoms, including psychomotor developmental delay, spasticity, nystagmus, impairment of cognitive skills, sensorineural hearing loss, and different ophthalmological disabilities. While clinical features overlap, PMD and PMLD1 can be distinguished on the molecular genetic level. PMD is caused by mutations in the gene encoding for the proteolipid protein 1 (PLP1), whereas PMLD1 is associated with mutations in the gene encoding for the gap junction protein gamma 2 (GJC2). Here we present novel compound-heterozygous mutations in the GJC2 gene identified in two, unrelated infantile patients affected with PMLD1. The heterozygous frameshift mutations c.392dupC, p.H132Afs*6 and c.989delC, p.P330Rfs*141 were found in the first patient. The heterozygous nonsense variant c.291C>G, p.Y97*, as well as the heterozygous missense variant c.716T>C, p.V239A were detected in the second patient. All four variants were predicted to be damaging for structure and/or function of the GJC2 protein. Combinations of these genetic variants likely are pathogenic and resulted in the PMLD1-phenotype in the investigated children. In conclusion, our clinical and molecular findings confirmed the genotype-phenotype relationship between mutations in the GJC2 and PMLD1. The novel mutations of GJC2 described herein will help to further understand the pathogenic mechanism underlying PMLD1.

Nocturnal frontal lobe epilepsy caused by a mutation in the GATOR1 complex gene NPRL3.

Mutations in NPRL3, one of three genes that encode proteins of the mTORC1-regulating GATOR1 complex, have recently been reported to cause cortical dysplasia with focal epilepsy. We have now analyzed a multiplex epilepsy family by whole exome sequencing and identified a frameshift mutation (NM_001077350.2; c.1522delG; p.E508Rfs*46) within exon 13 of NPRL3. This truncating mutation causes an epilepsy phenotype characterized by early childhood onset of mainly nocturnal frontal lobe epilepsy. The penetrance in our family was low (three affected out of six mutation carriers), compared to families with either ion channel- or DEPDC5-associated familial nocturnal frontal lobe epilepsy. The absence of apparent structural brain abnormalities suggests that mutations in NPRL3 are not necessarily associated with focal cortical dysplasia but might be able to cause epilepsy by different, yet unknown pathomechanisms.

Mutations in SLC33A1 cause a lethal autosomal-recessive disorder with congenital cataracts, hearing loss, and low serum copper and ceruloplasmin.

Low copper and ceruloplasmin in serum are the diagnostic hallmarks for Menkes disease, Wilson disease, and aceruloplasminemia. We report on five patients from four unrelated families with these biochemical findings who presented with a lethal autosomal-recessive syndrome of congenital cataracts, hearing loss, and severe developmental delay. Cerebral MRI showed pronounced cerebellar hypoplasia and hypomyelination. Homozygosity mapping was performed and displayed a region of commonality among three families at chromosome 3q25. Deep sequencing and conventional sequencing disclosed homozygous or compound heterozygous mutations for all affected subjects in SLC33A1 encoding a highly conserved acetylCoA transporter (AT-1) required for acetylation of multiple gangliosides and glycoproteins. The mutations were found to cause reduced or absent AT-1 expression and abnormal intracellular localization of the protein. We also showed that AT-1 knockdown in HepG2 cells leads to reduced ceruloplasmin secretion, indicating that the low copper in serum is due to reduced ceruloplasmin levels and is not a sign of copper deficiency. The severity of the phenotype implies an essential role of AT-1 in proper posttranslational modification of numerous proteins, without which normal lens and brain development is interrupted. Furthermore, AT-1 defects are a new and important differential diagnosis in patients with low copper and ceruloplasmin in serum.

Horizontal head titubation in infants with Joubert syndrome: a new finding.

AIM: Head thrusts are well documented in Joubert syndrome and ocular motor apraxia. We provide a detailed clinical characterization of head titubation in 13 young children with Joubert syndrome. METHOD: Detailed characterization of head titubation was assessed by targeted clinical evaluation and/or analysis of videos. RESULTS: In 12 of 13 children (eight males, five females; median age 6y, range 2mo-15y) head titubation was first recognized in the first 2 months of age and decreased in severity until spontaneous resolution. In all children, the head titubation was horizontal, high frequency (~3Hz), had small amplitude (5-10°), was never present during sleep, and did not interfere with the neurodevelopment during infancy. In the majority of children, emotion, anxiety, and tiredness were worsening factors for head titubation. INTERPRETATION: Head titubation is a benign, early presentation of Joubert syndrome. Head titubation in hypotonic infants should prompt a careful search for Joubert syndrome. Awareness of its occurrence in Joubert syndrome may avoid unnecessary investigations.

Molecular and biochemical characterization of a unique mutation in CCS, the human copper chaperone to superoxide dismutase.

Copper (Cu) is a trace metal that readily gains and donates electrons, a property that renders it desirable as an enzyme cofactor but dangerous as a source of free radicals. To regulate cellular Cu metabolism, an elaborate system of chaperones and transporters has evolved, although no human Cu chaperone mutations have been described to date. We describe a child from a consanguineous family who inherited homozygous mutations in the SLC33A1, encoding an acetyl CoA transporter, and in CCS, encoding the Cu chaperone for superoxide dismutase. The CCS mutation, p.Arg163Trp, predicts substitution of a highly conserved arginine residue at position 163, with tryptophan in domain II of CCS, which interacts directly with superoxide dismutase 1 (SOD1). Biochemical analyses of the patient's fibroblasts, mammalian cell transfections, immunoprecipitation assays, and Lys7Δ (CCS homolog) yeast complementation support the pathogenicity of the mutation. Expression of CCS was reduced and binding of CCS to SOD1 impaired. As a result, this mutation causes reduced SOD1 activity and may impair other mechanisms important for normal Cu homeostasis. CCS-Arg163Trp represents the primary example of a human mutation in a gene coding for a Cu chaperone.

Hyperphosphatasia-mental retardation syndrome due to PIGV mutations: expanded clinical spectrum.

Hyperphosphatasia-mental retardation syndrome is a recently delineated disorder associated with a recognizable facial phenotype and brachytelephalangy. This autosomal recessive condition is caused by homozygous and compound heterozygous missense mutations of PIGV, encoding a member of the GPI-anchor biosynthesis pathway. Here, we report on two further, unrelated patients with developmental delay, elevated serum levels of AP, distinctive facial features, hypoplastic terminal phalanges, anal atresia in one and Hirschsprung disease in the other patient. By sequencing PIGV we detected compound heterozygous mutations c.467G>A and c.1022C>A in Patient 1 and a homozygous mutation c.1022C>A in Patient 2. We reviewed the eight reported cases with proven PIGV mutations and re-defined the phenotypic spectrum associated with PIGV mutations: intellectual disability, the distinct facial gestalt, brachytelephalangy, and hyperphosphatasia are constant features but also anorectal malformations and Hirschsprung disease as well as cleft lip/palate and hearing impairment should be considered as part of the clinical spectrum. Moreover, seizures and muscular hypotonia are frequently associated with PIGV mutations.

A Novel de novo Frameshift Mutation in the BCL11A Gene in a Patient with Intellectual Disability Syndrome and Epilepsy.

Intellectual disability syndrome (IDS) associated with a hereditary persistence of fetal haemoglobin (HbF), also known as Dias-Logan syndrome, is commonly characterised by psychomotor developmental delay, intelectual disability, language delay, strabismus, thin upper lip, abnormalities of external ears, microcephaly, downslanting palpebral fissures. Sporadically, autism spectrum disorders and blue sclerae in infancy have been reported in IDS. Rarely, IDS-affected patients present with epilepsy and/or epileptic syndromes. It has been shown that a haploinsufficiency of the B cell leukaemia/lymphoma 11A gene (BCL11A) is responsible for IDS. Herein, we identified a novel de novo frameshift deletion (c.271delG; p.E91Afs*2) in the BCL11A gene in a boy affected with IDS. Interestingly, this heterozygous loss-of-function BCL11A mutation was also associated with a generalised idiopathic epilepsy and severe language delay observed in the patient. Moreover, our study showed that the combination of molecular genetic analyses with the monitoring of HbF was essential to make the final diagnosis of Dias-Logan syndrome. Because our patient suffered from well-controlled epilepsy, we propose to include the BCL11A gene in routinely used molecular genetic epilepsy-related gene panels. Additionally, many of the clinical features of IDS overlap with symptoms observed in patients with suspected alcohol spectrum disorders. Therefore, we also suggest monitoring HbF levels in patients with these syndromes to further facilitate clinical diagnosis.

Rare variants in the GABAA receptor subunit ε identified in patients with a wide spectrum of epileptic phenotypes.

BACKGROUND: Epilepsy belongs to a group of chronic and highly heterogeneous brain disorders. Many types of epilepsy and epileptic syndromes are caused by genetic factors. The neural amino acid y-aminobutyric acid (GABA) is a major inhibitory neurotransmitter in the mammalian central nervous system. It regulates activity of channel pores by binding to transmembrane GABA-receptors (GABRs). The GABRs are heteropentamers assembled from different receptor subunits (α1-6, ß1-3, γ1-3, δ, ε, θ, π, and ρ1-3). Several epileptic disorders are caused by mutations in genes encoding single GABRs. METHODS: We applied trio- and single-whole exome sequencing to search for genetic sequence variants associated with a wide range of epileptic phenotypes accompanied by intellectual disability and/or global developmental delay in the investigated patients. RESULTS: We identified four hemizygous sequence variants in the GABAA receptor subunit ε gene (GABRE), including one nonsense (NM_004961.3: c.399C>A, p.Tyr133*), two missense variants (NM_004961.3: c.664G>A, p.Glu222Lys; NM_004961.3: c.1045G>A, p.Val349Ile), and one variant affecting the translation initiation codon (NM_004961.3: c.1A>G, p.Met1?) in four unrelated families. CONCLUSION: Our clinical and molecular genetic findings suggest that GABRE is a likely candidate gene for epilepsy. Nevertheless, functional studies are necessary to better understand pathogenicity of the GABRE-mutations and their associations with epileptic phenotypes.

HACE1 deficiency leads to structural and functional neurodevelopmental defects.

OBJECTIVE: We aim to characterize the causality and molecular and functional underpinnings of HACE1 deficiency in a mouse model of a recessive neurodevelopmental syndrome called spastic paraplegia and psychomotor retardation with or without seizures (SPPRS). METHODS: By exome sequencing, we identified 2 novel homozygous truncating mutations in HACE1 in 3 patients from 2 families, p.Q209* and p.R332*. Furthermore, we performed detailed molecular and phenotypic analyses of Hace1 knock-out (KO) mice and SPPRS patient fibroblasts. RESULTS: We show that Hace1 KO mice display many clinical features of SPPRS including enlarged ventricles, hypoplastic corpus callosum, as well as locomotion and learning deficiencies. Mechanistically, loss of HACE1 results in altered levels and activity of the small guanosine triphosphate (GTP)ase, RAC1. In addition, HACE1 deficiency results in reduction in synaptic puncta number and long-term potentiation in the hippocampus. Similarly, in SPPRS patient-derived fibroblasts, carrying a disruptive HACE1 mutation resembling loss of HACE1 in KO mice, we observed marked upregulation of the total and active, GTP-bound, form of RAC1, along with an induction of RAC1-regulated downstream pathways. CONCLUSIONS: Our results provide a first animal model to dissect this complex human disease syndrome, establishing the first causal proof that a HACE1 deficiency results in decreased synapse number and structural and behavioral neuropathologic features that resemble SPPRS patients.

Novel DCC variants in congenital mirror movements and evaluation of disease-associated missense variants.

Congenital mirror movements (CMM) are involuntary movements of one side of the body that mirror intentional movements of the other side. Heterozygous missense, frameshift and nonsense variants and small intragenic deletions in DCC cause CMM, isolated agenesis of the corpus callosum (ACC) or both. We report here the clinical phenotype and natural history of ten individuals with CMM carrying five different monoallelic DCC variants, including the missense variant p.(Trp273Arg), two duplications, one deletion and one deletion-insertion; all are novel and absent from databases. We re-evaluated the 15 known disease-associated DCC missense variants by determining minor allele frequency (MAF) and pathogenicity using four in silico tools combining previous pathogenicity scores and the ACMG/AMP standards and guidelines and classified them in three groups. Group I contains three DCC missense variants that are rather unlikely to be associated with a higher risk to CMM and/or ACC. The five variants in group II may represent susceptibility factors to altered midline crossing in the central nervous system. Group III includes seven variants absent in publically available databases and representing possible pathogenic alleles, with four predicted to have a severe impact on protein function. Based on this data and the variable expressivity and incomplete penetrance present in heterozygous carriers of a DCC variant, classification and clinical interpretation of missense variants is challenging in the absence of evidence of pathogenicity originated from functional studies. Evaluation of missense variants by MAF and a weighted combination of several computational algorithms is recommended.

Clinical and genetic spectrum of AMPD2-related pontocerebellar hypoplasia type 9.

Pontocerebellar hypoplasia (PCH) represents a group of autosomal-recessive progressive neurodegenerative disorders of prenatal onset. Eleven PCH subtypes are classified according to clinical, neuroimaging and genetic findings. Individuals with PCH type 9 (PCH9) have a unique combination of postnatal microcephaly, hypoplastic cerebellum and pons, and hypoplastic or absent corpus callosum. PCH9 is caused by biallelic variants in AMPD2 encoding adenosine monophosphate deaminase 2; however, a homozygous AMPD2 frameshift variant has recently been reported in two family members with spastic paraplegia type 63 (SPG63). We identified homozygous or compound heterozygous AMPD2 variants in eight PCH-affected individuals from six families. The eight variants likely affect function and comprise one frameshift, one nonsense and six missense variants; seven of which were novel. The main clinical manifestations in the eight new patients and 17 previously reported individuals with biallelic AMPD2 variants were postnatal microcephaly, severe global developmental delay, spasticity, and central visual impairment. Brain imaging data identified hypomyelination, hypoplasia of the cerebellum and pons, atrophy of the cerebral cortex, complete or partial agenesis of the corpus callosum and the "figure 8" shape of the hypoplastic midbrain as consistent features. We broaden the AMPD2-related clinical spectrum by describing one individual without microcephaly and absence of the characteristic "figure 8" shape of the midbrain. The existence of various AMPD2 isoforms with different functions possibly explains the variability in phenotypes associated with AMPD2 variants: variants leaving some of the isoforms intact may cause SPG63, while those affecting all isoforms may result in the severe and early-onset PCH9.

Acute Liver Failure Meets SOPH Syndrome: A Case Report on an Intermediate Phenotype.

Acute liver failure (ALF) is a life-threatening condition in the absence of preexisting liver disease in children. The main clinical presentation comprises hepatic dysfunction, elevated liver biochemical values, and coagulopathy. The etiology of ALF remains unclear in most affected children; however, the recent identification of mutations in the neuroblastoma amplified sequence (NBAS) gene in autosomal recessively inherited ALF has shed light on the cause of a subgroup of fever-triggered pediatric ALF episodes. Previously, biallelic mutations in NBAS have been reported to be associated with a syndrome comprising short stature, optic atrophy, and Pelger-Huët anomaly (SOPH) specifically occurring in the Yakut population. No hepatic phenotype has been observed in individuals with this disorder who all carry the homozygous NBAS founder mutation c.5741G>A [p.(Arg1914His)]. We present the case of a 4-year-old girl with the cardinal features of SOPH syndrome: characteristic facial dysmorphism, postnatal growth retardation, delay of bone age, slender long bones, optic atrophy, and Pelger-Huët anomaly. During the first 2 years of her life, a series of infections with episodes of fever were accompanied by elevated liver enzyme levels, but hyperammonemia, hypoglycemia, coagulopathy, or encephalopathy suggestive of acute and severe liver disease were never observed. Whole exome sequencing in the patient revealed compound heterozygosity of the 2 NBAS variants, p.(Arg1914His) and p.(Glu943*). This case highlights the variability of clinical presentation associated with NBAS deficiency. Absence of severe liver problems in this case and SOPH-affected Yakut subjects suggests that individuals carrying the NBAS missense mutation p.(Arg1914His) are less susceptible to developing ALF.

Novel mutations in BCOR in three patients with oculo-facio-cardio-dental syndrome, but none in Lenz microphthalmia syndrome.

Oculo-facio-cardio-dental (OFCD) syndrome is a rare X-linked dominant condition with male lethality characterized by microphthalmia, congenital cataracts, facial dysmorphic features, congenital heart defects, and dental anomalies. Mutations in BCOR (BCL6 co-repressor) located in Xp11.4 have been described to cause OFCD syndrome. Lenz microphthalmia syndrome is inherited in an X-linked recessive pattern comprising microphthalmia/anophthalmia, mental retardation, malformed ears, digital, skeletal, and urogenital anomalies (synonym: microphthalmia with associated anomalies (MAA)). One locus for MAA has been mapped to Xq27-q28. Nonetheless, linkage and subsequent mutation analysis revealed a single missense mutation (p.P85L) in BCOR in a large family with presumed Lenz microphthalmia syndrome (MAA2). We describe novel mutations in BCOR in three patients with OFCD syndrome, two small deletions (c.2488_2489delAG and c.3286delG) and a submicroscopic deletion of about 60 kb encompassing at least BCOR exons 2-15. No BCOR mutation was detected in eight patients with Lenz microphthalmia syndrome. Our data confirm that BCOR is the causative gene for OFCD syndrome; however, the failure to identify any mutation in patients with Lenz microphthalmia syndrome together with the oligosymptomatic phenotype in the reported MAA2 patients suggest that BCOR is not the major gene for this syndrome.

Mutations in KCNH1 and ATP6V1B2 cause Zimmermann-Laband syndrome.

Zimmermann-Laband syndrome (ZLS) is a developmental disorder characterized by facial dysmorphism with gingival enlargement, intellectual disability, hypoplasia or aplasia of nails and terminal phalanges, and hypertrichosis. We report that heterozygous missense mutations in KCNH1 account for a considerable proportion of ZLS. KCNH1 encodes the voltage-gated K(+) channel Eag1 (Kv10.1). Patch-clamp recordings showed strong negative shifts in voltage-dependent activation for all but one KCNH1 channel mutant (Gly469Arg). Coexpression of Gly469Arg with wild-type KCNH1 resulted in heterotetrameric channels with reduced conductance at positive potentials but pronounced conductance at negative potentials. These data support a gain-of-function effect for all ZLS-associated KCNH1 mutants. We also identified a recurrent de novo missense change in ATP6V1B2, encoding the B2 subunit of the multimeric vacuolar H(+) ATPase, in two individuals with ZLS. Structural analysis predicts a perturbing effect of the mutation on complex assembly. Our findings demonstrate that KCNH1 mutations cause ZLS and document genetic heterogeneity for this disorder.

Pontocerebellar hypoplasia type 2 and TSEN2: review of the literature and two novel mutations.

Pontocerebellar hypoplasias (PCH) represent a heterogeneous group of autosomal recessive neurodegenerative disorders characterized by hypoplasia of the cerebellum and pons, variable cerebral involvement, microcephaly, severe delay in cognitive and motor development, and seizures. Seven different subtypes have been reported (PCH1-7) and mutations in three genes, TSEN2, TSEN34 and TSEN54 encoding three of four subunits of the tRNA splicing endonuclease complex have been found to underlie PCH2, PCH4 and PCH5. PCH2 is characterized by cerebellar hypoplasia affecting the hemispheres more severely than the vermis, progressive cerebral atrophy and microcephaly, dyskinesia, seizures, and death in early childhood. We describe a male patient with progressive microcephaly, severe hypotonia, and myoclonic-tonic seizures. Brain MRI confirmed microcephaly with simplified cortical gyration and revealed hypoplasia of the brainstem, cerebellum and cerebellar vermis. Sequencing of the TSEN2 gene detected the novel missense mutation c.934G > A (p.G312R) on one allele and the first nonsense mutation c.691C > T (p.Q231*) on the second allele. Although the cytosine-to-thymine transition results in introduction of a premature stop codon in the majority of annotated TSEN2 transcript variants, it could represent a splice site mutation (c.517-3C > T) in variant 4. However, by RT-PCR analysis we did not identify mRNAs representing TSEN2 transcript form 4 in leukocyte-derived RNA of the patient and healthy individuals. The clinical phenotype of the patient is comparable with PCH2. However, we noticed decreased cerebral volume with increased extra-axial cerebrospinal fluid spaces and wide-open Sylvian fissures indicating cerebral immaturity that might be associated with the TSEN2 null allele. We conclude that the severity of pontocerebellar hypoplasia in the patient fits PCH2, while the large involvement of the cerebrum better corresponds to PCH4 demonstrating the phenotypic spectrum of PCH2 and 4. To establish a possible genotype-phenotype correlation, more individuals with biallelic TSEN2 mutations need to be investigated.

Mutations in KIF7 link Joubert syndrome with Sonic Hedgehog signaling and microtubule dynamics.

Joubert syndrome (JBTS) is characterized by a specific brain malformation with various additional pathologies. It results from mutations in any one of at least 10 different genes, including NPHP1, which encodes nephrocystin-1. JBTS has been linked to dysfunction of primary cilia, since the gene products known to be associated with the disorder localize to this evolutionarily ancient organelle. Here we report the identification of a disease locus, JBTS12, with mutations in the KIF7 gene, an ortholog of the Drosophila kinesin Costal2, in a consanguineous JBTS family and subsequently in other JBTS patients. Interestingly, KIF7 is a known regulator of Hedgehog signaling and a putative ciliary motor protein. We found that KIF7 co-precipitated with nephrocystin-1. Further, knockdown of KIF7 expression in cell lines caused defects in cilia formation and induced abnormal centrosomal duplication and fragmentation of the Golgi network. These cellular phenotypes likely resulted from abnormal tubulin acetylation and microtubular dynamics. Thus, we suggest that modified microtubule stability and growth direction caused by loss of KIF7 function may be an underlying disease mechanism contributing to JBTS.